School of PhysicsSchool of Physicshttp://hdl.handle.net/2262/142017-09-26T21:43:23Z2017-09-26T21:43:23ZArticle Quantifying the Performance of P-Type Transparent Conducting Oxides by Experimental MethodsFLEISCHER, KARSTENNORTON, EMMAMULLARKEY, DARAGHCAFFREY, DAVIDSHVETS, IGORhttp://hdl.handle.net/2262/817952017-09-22T02:03:45Z2017-01-01T00:00:00ZArticle Quantifying the Performance of P-Type Transparent Conducting Oxides by Experimental Methods
FLEISCHER, KARSTEN; NORTON, EMMA; MULLARKEY, DARAGH; CAFFREY, DAVID; SHVETS, IGOR
PUBLISHED
2017-01-01T00:00:00ZTowards data-driven magnetic materials discoveryZIC, MARIOhttp://hdl.handle.net/2262/805622017-07-11T02:02:12Z2017-01-01T00:00:00ZTowards data-driven magnetic materials discovery
ZIC, MARIO
Magnetic materials underpin many of the technologies that define the world we live in. Despite the tremendous technological progress, the discovery of new magnetic materials has been rather slow. In this Thesis we explore and develop new, data-oriented, methods for the accelerated discovery and development of new magnetic materials. We utilize available theoretical databases of Heusler alloy properties to: develop a high-throughput (HT) screening procedure for the discovery of new permanent magnets, identify the defects in Mn-Ru-Ga thin films, and build machine learning (ML) models for predicting the structural and the magnetic properties of Heusler alloys. We identify a dozen materials, which meet all of the criteria for permanent magnet applications. The analysis of the HT data allowed us to understand the ideal composition of hard magnetic materials in the family of regular Heusler alloys, and to show how structure-property constraints affect the abundance of the potential candidates for technological applications. We find that hard permanent magnets occur with a frequency smaller than 1 in 10 000, with respect to the overall population of the regular Heusler alloys in the database. We then demonstrate that the ML techniques can be used both to improve the efficiency of the HT procedure and to perform a data-driven investigation of the material properties. In the case of the Mn-Ru-Ga thin films we show how the HT data can be utilized to guide the modeling of technologically relevant materials. The HT data was used to identify the nature of the defects that occur in the films, and hence, to obtain an accurate theoretical description of the material properties. We build ML models to investigate the magnetism of Fe in Heusler alloys. We then study how the local chemical environment affects its magnetic moment and thus address the structure-property relationship directly. We also show that new knowledge about the physics of materials can be extracted directly from the data. This work clearly demonstrates the potential that ML techniques have to offer in the analysis of a vast amount of materials data and paves the way for the future data-driven studies of magnetism.
APPROVED
2017-01-01T00:00:00ZLocalised surface plasmon mediated energy transfer in quantum dot systemsZhang, Xiahttp://hdl.handle.net/2262/805522017-06-29T02:09:59Z2015-01-01T00:00:00ZLocalised surface plasmon mediated energy transfer in quantum dot systems
Zhang, Xia
Nonradiative energy transfer to metal nanoparticles (NPs) is a technique used for optical- based distance measurements which is often implemented in sensing. Both Forster resonant energy transfer (FRET) and nanometal surface energy transfer (NSET) mechanisms have been proposed for emission quenching in proximity to metal NPs. Here quenching of emission of colloidal quantum dots (QD) in proximity to a monolayer of gold NPs is investigated. Five differently sized CdTe QDs are used to probe the wavelength dependence of the quenching mechanism as their emission peak moves from on resonance to off resonance with respect to the localized surface plasmon (LSP) peak of the Au NP layer.
2015-01-01T00:00:00ZDevelopment of a cantilever based device for the investigation of malaria vaccine cross-reactivityWalther, Michaelhttp://hdl.handle.net/2262/805422017-06-29T02:09:45Z2015-01-01T00:00:00ZDevelopment of a cantilever based device for the investigation of malaria vaccine cross-reactivity
Walther, Michael
The invention of the atomic force microscope and subsequent implementation of cantilevers as transducers for sensing applications laid the foundation for the current use of cantilevers as biosensors. This application involves functionalisation of the surface with a bio-recognition layer, immersion of the sensors in a physiological environment and operation in either the static or the dynamic mode to transduce the biological interaction into a measurable signal. When operated in dynamic mode, the cantilever is actuated at its resonance frequency. Mass uptake on the sensor results in a resonance frequency shift, thereby transforming the cantilever into a sensitive microbalance.
2015-01-01T00:00:00Z